Oxyhalide precursors

Info

Patent number: 11919780
Type: Grant
Filed: Jul 8, 2020
Date of Patent: Mar 5, 2024
Patent Publication Number: 20210009437
Assignee: ENTEGRIS, INC. (Billerica, MA)
Inventors: David M. Ermert (Danbury, CT), Robert L. Wright, Jr. (Newtown, CT), Thomas H. Baum (New Fairfield, CT), Bryan C. Hendrix (Danbury, CT)
Primary Examiner: Coris Fung
Assistant Examiner: Keling Zhang
Application Number: 16/923,899

Abstract

The invention provides a process for preparing molybdenum and tungsten oxyhalide compounds which are useful in the deposition of molybdenum and tungsten containing films on various surfaces of microelectronic devices. In the process of the invention, a molybdenum or tungsten trioxide is heated in either a solid state medium or in a melt-phase reaction comprising a eutectic blend comprising alkaline and/or alkaline earth metal salts. The molybdenum or tungsten oxyhalides thus formed may be isolated as a vapor and crystallized to provide highly pure precursor compounds such as MoO2Cl2.

Description

Description

FIELD OF THE INVENTION

The present invention relates to certain precursors for the vapor deposition of certain Group VI-containing materials, a method for their preparation, and novel crystal structures thereof.

BACKGROUND OF THE INVENTION

In consequence of its characteristics of extremely high melting point, low coefficient of thermal expansion, low resistivity, and high thermal conductivity, Group VI metals such as molybdenum and tungsten are increasingly utilized in the manufacture of semiconductor devices, including use in diffusion barriers, electrodes, photomasks, power electronics substrates, low-resistivity gates, and interconnects.

Such utility has motivated efforts to achieve deposition of molybdenum and tungsten films for such applications that is characterized by high conformality of the deposited film and high deposition rate to accommodate efficient high-volume manufacturing operations. This in turn has motivated efforts to develop improved molybdenum and tungsten source reagents useful in vapor deposition operations, as well as improved process parameters utilizing such reagents.

Molybdenum pentachloride is most commonly used as a molybdenum source for chemical vapor deposition of molybdenum-containing material. Another source reagent or precursor is MoO₂Cl_2,but there remains a need to prepare such reagents in high yield and purity, along with other oxyhalides such as WOCl_4,WO₂Cl_2,MoOCl_4,and the like.

SUMMARY OF THE INVENTION

The invention provides a process for preparing certain Group VI metal oxyhalide compounds which are useful in the deposition of Group VI containing films on various surfaces of microelectronic devices. In the process of the invention, a molybdenum or tungsten trioxide is heated in either a solid state medium or in a melt-phase reaction comprising a eutectic blend comprising one or more alkaline and/or alkaline earth metal salts. The molybdenum or tungsten oxyhalide thus formed may be isolated as a vapor and crystallized to provide highly pure crystalline oxyhalides such as MoO₂Cl₂and WO₂Cl₂to provide another aspect of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a crystal structure depiction of the MoO₂Cl₂unit cell.

FIG. 2 depicts a thermogravimetric analysis of MoO₃and LiCl/KCl mixtures displaying appreciable mass loss upon combination of MoO₃and LiCl/KCl. Residual mass (%) is plotted versus Temperature (° C.)

FIG. 3 depicts a thermogravimetric analysis comparing commercially available MoO₂Cl₂and synthesized MoO₂Cl₂using the method of the invention. Residual mass (%) is plotted versus Temperature (° C.).

FIG. 4 is an FTIR comparison of purchased MoO₂Cl₂versus MoO₂Cl₂prepared using the method of the invention.

FIG. 5 is a plot of the experimental X-ray powder diffraction of MoO₂Cl₂crystals compared to the calculated spectra (black lines) using the obtained MoO₂Cl₂unit cell parameters.

FIG. 6 is the X-ray powder diffraction of hydrated MoO₂Cl₂with the simulated MoO₂Cl₂illustrated below as solid vertical lines.

FIG. 7 is a simultaneous thermogravimetric analysis coupled with differential scanning calorimetry (STA-DSC) of the described method. This data shows that a melting point occurs at a temperature slightly different than at the LiCl/KCl eutectic alone.

DETAILED DESCRIPTION OF THE INVENTION

In a first aspect, the invention provides a process for preparing compounds of the formula MO_yX_z, wherein M is chosen from molybdenum, and tungsten, and X is chosen from chloro, fluoro, bromo, and iodo, y is 1 or 2, and z is 2 or 4, which comprises contacting a compound of the formula

with at least one compound of the formula A-X, wherein A is chosen from elements of Group 1, Group 2, transitions metals, and main-group elements of the Periodic Table, at a temperature of about 200° to about 900° C.

As set forth herein, A can be any element capable of forming a halide.

In one embodiment, A is chosen from alkali and alkaline earth metals.

In one embodiment, A is chosen from lithium, sodium, and potassium. In another embodiment, A is chosen from magnesium, calcium, strontium, barium, beryllium, scandium, titanium, vanadium, and chromium. In another embodiment, A is lithium or potassium.

In one embodiment, X is chloro.

In another embodiment, the at least one compound of the formula A-X is a mixture of two or more compounds, and in certain embodiments, said compounds are chosen so as to form a eutectic mixture.

In the process of the invention, while the interaction of the compound of the formula A-X and the compound of the formula MO₃can occur while A-X is in a solid state throughout the temperature range of about 200° to about 900°, the compounds of the formula A-X can also be advantageously chosen from those alkali metal halides and alkaline earth metal halides which form eutectic blends. In this manner, eutectic blends of two or more compounds of the formula A-X allow for the practice of the process of the invention in the melt phase at processing temperatures lower than the melting point of each individual alkali metal halide or alkaline earth metal halide, while at the same time providing a melt phase reaction environment which facilitates the sublimation of the compounds of the formula MO_yX_zas formed, which can then be removed and allowed to cool to provide a pure crystalline form. Various blends of compounds of the formula A-X may be chosen and in varying proportions in order to provide a suitable reaction medium and halide source while providing at the same time a sufficiently high temperature melt phase to facilitate sublimation of the desired product as it is formed. In certain embodiments, the proportions of the individual alkali metal halides and alkaline earth metal halides may be approximately 1:1, but may also be varied from 10:1 or 1:10, depending on whatever concentration of either component of the blend is necessary to provide a melt phase reaction medium in the desired temperature range. In other embodiments, the mixture defined by the formula A-X may comprise three or more species which form a eutectic blend which forms a melt phase within the desired temperature range for the formation and sublimation of the products of the formula MO_yX_z.

Many compounds of the formula A-X are known to form eutectic blends, for example, LiCl/KCl, as recited in the experimental section below, along with those set forth in “Molten Salts: Volume 4, Part 2 Chlorides and Mixtures—electrical conductance, density, viscosity, and surface tension data”, G. J. Janz et al., Journal of Physical and Chemical Reference Data 4, 871 (1975).

In one embodiment, the compounds of the formula A-X are a mixture of lithium chloride and potassium chloride, which form a eutectic mixture having a melting point of about 357° C., in proportions of about 44 weight percent of lithium chloride to about 56 weight percent of potassium chloride.

In certain embodiments, the process is conducted utilizing inert carrier gasses such as nitrogen, argon, etc., either at atmospheric pressure or under reduced pressure, such parameters chosen to facilitate the sublimation of the desired reaction products of the formula MO_yX_z, as well as to minimize thermal decomposition of the desired product. Additionally, in one embodiment, the stoichiometric amount of the starting material of the formula MO₃is chosen so as to lead to a higher production of compounds of the formula MO_yX_z, when Y is 1 and Z is 4. In another embodiment, the stoichiometric amount of the starting material of the formula MO₃is chosen so as to lead to a higher production of compounds of the formula MO_yX_z, when Y is 2 and Z is 2. In a further embodiment, the process is conducted under a regime of fractional sublimation, while varying the pressure and temperature so as to generate a given species at different pressure/temperature combinations. In this manner, species of desired product where Y and Z are 2 can be separated from species of desired product where Y is 1 and Z is 4, each forming a pure crystalline form upon cooling.

In a second aspect, the invention provides compounds having the formula MO_yX_zin crystalline form, wherein M is chosen from molybdenum and tungsten, X is chosen from chloro, fluoro, bromo, and iodo, and y is 1 or 2, and z is 2 or 4.

In one embodiment, the compound of the formula MO_yX_zis MoO₂Cl_2.In another embodiment, the crystalline form of the compound of the formula MoO₂Cl₂possesses a crystal structure as depicted in FIG. 1; this crystalline form of MoO₂Cl₂is anhydrous. In another embodiment, the crystalline form of the compound of the formula MoO₂Cl₂possesses an orthorhombic crystal system, and unit cell dimensions of about

a=13.552(5) Åα=90°

b=5.456(2) Åβ=90°

c=5.508(2) Åγ=90°.

The approximate bond lengths in the crystalline form of the compound of the formula MoO₂Cl₂have been determined to be as follows:

Mo—Cl 2.278(2) Å

Mo—O 1.706(5)-2.239(5) Å

Cl—Mo—Cl 151.78(7) Å

O—Mo—O 79.08-102.90 Å.

As used herein the term “unit cell” refers to the smallest and simplest volume element of a crystal that is completely representative of the unit of pattern of the crystal. The dimensions of the unit cell are defined by six numbers: dimensions a, b, and c and angles α, β, and γ. A crystal is an efficiently packed array of many unit cells.

As used herein, the term “orthorhombic unit cell” refers to a unit cell wherein a≠b≠c; α=β=γ=90°.

As used herein, “crystal lattice” refers to the array of points defined by the vertices of packed unit cells, as determined by single-crystal x-ray diffraction analysis.

As used herein, “space group” refers to the symmetry of a unit cell. In a space group designation (e.g., C2) the capital letter indicates the lattice type and the other symbols represent symmetry operations that can be carried out on the unit cell without changing its appearance.

In another embodiment, the crystalline form of MoO₂Cl₂exhibits a powder XRD pattern with one or more peaks at 12.94, 23.64, 26.10, 39.50, and/or 40.28±0.04 degrees 2-theta. In a further embodiment, the crystalline form of MoO₂Cl₂has a powder XRD pattern as depicted in FIG. 5. In another embodiment, crystalline MoO₂Cl₂has a powder XRD pattern with one or more peaks as determined from the single crystal unit cell parameters listed in Table 4.

In another embodiment, the compound of the formula MO_yX_zin crystalline form is WO₂Cl₂.

This invention can be further illustrated by the following examples of certain embodiments thereof, although it will be understood that these examples are included merely for purposes of illustration and are not intended to limit the scope of the invention unless otherwise specifically indicated.

EXAMPLES Example 1. Synthesis of MoO₂Cl₂

A (44/56 by weight) mixture of lithium chloride and potassium chloride was combined with MO₃in a stainless steel ampule and evacuated under reduced pressure (20 mTorr). The ampule was heated to 475° C. inside a tube furnace. The resulting MoO₂Cl₂vapor was collected via a short-path tube equipped with a round bottom flask. FTIR and STA analysis supports the synthesis of MoO₂Cl₂.

TABLE 1 4 (ICP-MS data on MoO₂Cl₂synthesized using the described method. Data reported in parts-per-million (ppm)). Element list D.L. Sample A* Sample B Sample C Aluminum 0.041 0.523 0.354 0.571 Antimony 0.027 0.786 0.690 0.606 Barium 0.018 0.019 <0.018 <0.018 Calcium 1.851 1.851 1.272 0.919 Chromium 0.027 <0.027 <0.027 <0.027 Cobalt 0.026 <0.026 <0.026 <0.026 Copper 0.028 <0.028 <0.028 <0.028 Iron 0.028 0.482 0.404 0.704 Lead 0.023 <0.023 <0.023 <0.023 Lithium 0.036 0.238 0.067 0.133 Magnesium 0.032 0.081 0.065 0.092 Manganese 0.021 <0.021 <0.021 <0.021 Nickel 0.022 0.033 0.056 0.045 Potassium 0.019 1.019 2.259 2.731 Silver 0.027 <0.027 <0.027 <0.027 Sodium 0.066 0.083 0.165 0.329 Tin 0.043 0.115 0.119 0.409 Titanium 0.067 <0.067 <0.067 0.068 Vanadium 0.027 <0.027 <0.027 <0.027 *Each of samples A, B, and C were taken from the same lot.

TABLE 2 Crystal data and structure refinement for MoO₂Cl₂ Identification code NB00657 Empirical formula Cl₂Mo O₂ Formula weight 198.84 Temperature 100.0 K Wavelength 0.71073 Å Crystal system Orthorhombic Space group Cmc21 Unit cell dimensions a = 13.552(5) Å α = 90°. b = 5.456(2) Å β = 90°. c = 5.508(2) Å γ = 90°. Volume 407.2(3) Å3 Z 4 Density (calculated) 3.243 Mg/m3 Absorption coefficient 4.342 mm−1 F(000) 368 Crystal size 0.27 × 0.22 × 0.2 mm3 Theta range for data 3.006 to 28.284°. collection Index ranges −17 <= h <= 17, −7 <= k <= 5, −7 <= l <= 7 Reflections collected 1579 Independent reflections 523 [R(int) = 0.0274] Completeness to 100.0% theta = 25.500° Absorption correction Semi-empirical from equivalents Max. and min. transmission 0.2627 and 0.1831 Refinement method Full-matrix least-squares on F2 Data/restraints/parameters 523/1/28 Goodness-of-fit on F² 1.144 Final R indices R1 = 0.0216, wR2 = 0.0540 [I > 2sigma(I)] R indices (all data) R1 = 0.0234, wR2 = 0.0556 Absolute structure 0.12(5) parameter Extinction coefficient n/a Largest diff. peak and hole 1.383 and −0.853 e. Å−3

TABLE 3 Bond lengths [Å] and angles [°] for MoO₂Cl₂. Mo(1)—Cl(1)#1 2.2783 (17) Mo(1)—Cl(1) 2.2783 (17) Mo(1)—O(1) 1.715 (5) Mo(1)—O(1)#2 2.234 (6) Mo(1)—O(2) 1.706 (5) Mo(1)—O(2)#3 2.239 (5) Cl(1)#1—Mo(1)—Cl(1) 151.78 (7) O(1)#2—Mo(1)—Cl(1) 79.41 (4) O(1)—Mo(1)—Cl(1)#1 98.91 (5) O(1)—Mo(1)—Cl(1) 98.91 (5) O(1)#2—Mo(1)—Cl(1)#1 79.41 (4) O(1)—Mo(1)—O(1)#2 88.36 (11) O(1)#2—Mo(1)—O(2)#3 79.1 (3) O(1)—Mo(1)—O(2)#3 167.4 (3) O(2)—Mo(1)—Cl(1)#1 98.54 (5) O(2)#3—Mo(1)—Cl(1) 78.92 (4) O(2)#3—Mo(1)—Cl(1)#1 78.92 (4) O(2)—Mo(1)—Cl(1) 98.54 (5) O(2)—Mo(1)—O(1) 103.0 (4) O(2)—Mo(1)—O(1)#2 168.6 (3) O(2)—Mo(1)—O(2)#3 89.57 (6) Mo(1)—O(1)—Mo(1)#4 149.9 (4) Mo(1)—O(2)—Mo(1)#5 173.8 (4) Symmetry transformations used to generate equivalent atoms: #1 −x + 1, y, z #2 −x + 1, −y + 1, z + 1/2 #3 −x + 1, −y, z + 1/2 #4 −x + 1, −y + 1, z − 1/2 #5 −x + 1, −y, z − 1/2

TABLE 4 0.5(Cl₄Mo₂O₄) MoO₂Cl₂.cif MoO₂Cl₂ 0.5(Cl4Mo2O4) Orthorhombic: Cmc21 (36) [M = 8] CELL: 13.552 × 5.456 × 5.508 <90.0 × 90.0 × 90.0> oC20 Vol = 407.3, Z = 4, Dx = 3.2428, I/Ic = 8.14 See Dolomanov, O. V., Bourhis, L. J., Gildea, R. J, Howard, J. A. K. & Puschmann, H. (2009), J. Appl. Cryst. 42, 339-341. Sheldrick, G. M. (2008). Acta Cryst. A64, 112-122. _cell_measurement_reflns_used = 1075, _cell_measurement_temperature = 100(2), _cell_measurement_theta_max = 28.28, _cell_measurement_theta_min = 3.01 99 Merged Lines in 0.0-90.0 degs >= 0.0%, I/Ic = 8.14 (m [Diffractometer LP] [U(i, j)] = merged line): [F′ + F″] # (hkl) 2-Theta d(Å) I(f) Theta 1/(2d) 2pi/d m 1 (200) 13.055 6.776 57.9 6.527 0.0738 0.9273 2 (110) 17.508 5.0612 0.1 8.754 0.0988 1.2414 3 (111) 23.857 3.7268 100.0 11.929 0.1342 1.6860 4 (310) 25.580 3.4795 0.3 12.790 0.1437 1.8058 5 (400) 26.283 3.3880 8.8 13.142 0.1476 1.8545 6 (311) 30.360 2.9417 10.5 15.180 0.1700 2.1359 7 (2) 32.485 2.7540 8.0 16.242 0.1816 2.2815 8 (20) 32.803 2.7280 12.3 16.401 0.1833 2.3032 9 (202) 35.146 2.5513 7.3 17.573 0.1960 2.4627 10 (220) 35.443 2.5306 1.3 17.722 0.1976 2.4829 11 (21) 36.734 2.4446 0.1 18.367 0.2045 2.5702 12 (510) 37.004 2.4274 0.0 18.502 0.2060 2.5885 13 (112) 37.136 2.4191 0.7 18.568 0.2067 2.5974 14 (221) 39.143 2.2995 0.5 19.571 0.2174 2.7324 15 (600) 39.880 2.2587 13.5 19.940 0.2214 2.7818 16 (511) 40.582 2.2212 19.0 20.291 0.2251 2.8287 17 (312) 41.797 2.1594 0.4 20.898 0.2315 2.9096 18 (402) 42.256 2.1370 4.4 21.128 0.2340 2.9401 19 (420) 42.510 2.1248 0.6 21.255 0.2353 2.9571 20 (421) 45.730 1.9824 0.3 22.865 0.2522 3.1695 21 (22) 46.837 1.9381 10.8 23.419 0.2580 3.2419 22 (222) 48.835 1.8634 8.5 24.418 0.2683 3.3719 23 (710) 49.945 1.8245 0.0 24.973 0.2740 3.4437 24 (512) 50.049 1.8210 0.2 25.025 0.2746 3.4504 25 (130) 50.599 1.8025 0.0 25.299 0.2774 3.4858 26 (602) 52.344 1.7464 3.6 26.172 0.2863 3.5977 27 (620) 52.561 1.7397 5.5 26.280 0.2874 3.6116 28 (711) 52.814 1.7320 9.8 26.407 0.2887 3.6277 29 (113) 53.013 1.7259 5.6 26.507 0.2897 3.6404 30 (131) 53.442 1.7131 9.7 26.721 0.2919 3.6677 31 (800) 54.094 1.6940 1.3 27.047 0.2952 3.7091 32 (330) 54.334 1.6871 0.2 27.167 0.2964 3.7243 33 (422) 54.501 1.6823 5.7 27.250 0.2972 3.7349 34 (621) 55.333 1.6590 0.0 27.666 0.3014 3.7874 35 (313) 56.637 1.6238 8.1 28.319 0.3079 3.8694 36 (331) 57.048 1.6131 1.6 28.524 0.3100 3.8951 37 (23) 60.758 1.5232 0.1 30.379 0.3283 4.1251 38 (712) 60.853 1.5210 0.1 30.426 0.3287 4.1309 39 (530) 61.336 1.5102 0.0 30.668 0.3311 4.1605 40 (132) 61.426 1.5082 0.0 30.713 0.3315 4.1660 41 (223) 62.442 1.4861 0.1 31.221 0.3365 4.2280 42 (622) 63.163 1.4708 7.2 31.581 0.3399 4.2718 43 (513) 63.477 1.4643 3.0 31.739 0.3415 4.2909 44 (531) 63.861 1.4564 4.6 31.930 0.3433 4.3141 45 (910) 64.103 1.4515 0.0 32.052 0.3445 4.3287 46 (802) 64.533 1.4429 1.0 32.266 0.3465 4.3546 47 (820) 64.723 1.4391 0.4 32.361 0.3474 4.3660 48 (332) 64.748 1.4386 0.2 32.374 0.3476 4.3676 49 (911) 66.570 1.4036 0.9 33.285 0.3562 4.4765 50 (821) 67.177 1.3924 0.1 33.589 0.3591 4.5126 51 (423) 67.350 1.3892 0.1 33.675 0.3599 4.5228 52 (4) 68.029 1.3770 0.4 34.014 0.3631 4.5630 53 (40) 68.767 1.3640 1.8 34.384 0.3666 4.6064 54 (10, 0, 0) 69.277 1.3552 0.3 34.639 0.3689 4.6364 55 (204) 69.617 1.3494 1.8 34.808 0.3705 4.6562 56 (240) 70.348 1.3372 0.8 35.174 0.3739 4.6988 57 (114) 70.864 1.3287 0.0 35.432 0.3763 4.7288 58 (730) 71.059 1.3255 0.0 35.529 0.3772 4.7401 59 (532) 71.143 1.3242 0.0 35.571 0.3776 4.7450 60 (41) 71.153 1.3240 0.1 35.577 0.3776 4.7456 61 (241) 72.711 1.2994 0.3 36.355 0.3848 4.8353 62 (713) 73.054 1.2942 1.8 36.527 0.3863 4.8550 63 (731) 73.412 1.2887 3.4 36.706 0.3880 4.8755 64 (133) 73.578 1.2862 1.6 36.789 0.3887 4.8849 65 (912) 73.723 1.2841 0.0 36.861 0.3894 4.8932 66 (314) 73.971 1.2804 0.1 36.986 0.3905 4.9073 67 (404) 74.291 1.2757 1.6 37.145 0.3920 4.9254 68 (822) 74.304 1.2755 1.9 37.152 0.3920 4.9262 69 (440) 75.003 1.2653 0.5 37.501 0.3952 4.9657 70 (623) 75.174 1.2628 0.1 37.587 0.3959 4.9754 71 (333) 76.643 1.2423 3.1 38.322 0.4025 5.0579 72 (441) 77.311 1.2332 0.2 38.656 0.4055 5.0951 73 (24) 77.603 1.2293 0.3 38.802 0.4067 5.1113 74 (42) 78.130 1.2223 1.2 39.065 0.4091 5.1405 75 (10, 0, 2) 78.616 1.2160 0.6 39.308 0.4112 5.1673 76 (10, 2, 0) 78.791 1.2137 0.1 39.396 0.4120 5.1769 77 (224) 79.115 1.2095 2.6 39.558 0.4134 5.1947 78 (242) 79.639 1.2029 1.3 39.820 0.4157 5.2234 79 (11, 1, 0) 79.730 1.2017 0.0 39.865 0.4161 5.2284 80 (514) 80.053 1.1977 0.0 40.027 0.4175 5.2460 81 (732) 80.321 1.1944 0.0 40.160 0.4186 5.2606 82 (10, 2, 1) 81.068 1.1853 0.0 40.534 0.4218 5.3011 83 (604) 81.864 1.1757 0.4 40.932 0.4253 5.3441 84 (11, 1, 1) 82.000 1.1741 1.6 41.000 0.4259 5.3514 85 (640) 82.557 1.1676 2.0 41.279 0.4282 5.3812 86 (533) 82.667 1.1663 1.1 41.334 0.4287 5.3871 87 (930) 83.233 1.1598 0.0 41.617 0.4311 5.4173 88 (424) 83.610 1.1556 2.4 41.805 0.4327 5.4373 89 (442) 84.128 1.1498 1.1 42.064 0.4349 5.4648 90 (641) 84.812 1.1422 0.1 42.406 0.4377 5.5008 91 (913) 85.141 1.1387 2.1 42.571 0.4391 5.5181 92 (931) 85.486 1.1349 0.4 42.743 0.4406 5.5361 93 (823) 85.701 1.1326 0.0 42.851 0.4414 5.5474 94 (12, 0, 0) 86.013 1.1293 0.9 43.006 0.4427 5.5636 95 (10, 2, 2) 87.827 1.1106 1.1 43.913 0.4502 5.6574 96 (11, 1, 2) 88.750 1.1014 0.0 44.375 0.4539 5.7045 97 (714) 88.988 1.0991 0.0 44.494 0.4549 5.7166 98 (43) 89.421 1.0949 0.0 44.710 0.4567 5.7385 99 (134) 89.491 1.0942 0.1 44.745 0.4569 5.7421

Table 4 is the simulated Powder X-ray Diffraction (PXRD) spectra using the unit cell (MoO₂Cl₂crystal structure) using commercially-available software to model and simulate PXRD data.

TABLE 5 Hydrated MoO₂Cl₂ Peak Search Report SCAN: 10.0/90.0/0.032/43.5(sec), Cu, I(p) = 8121, 05/22/1 9 11: 28p PEAK: 15(pts)/Parabolic Filter, Threshold = 3.0, Cutoff = 0.1%, BG = 3/10, Peak-To . . . NOTE: Intensity = Counts, 2T(0) = 0.0(deg), Wavelength to Compute d-Spacing = . . . # 2-Theta d(Å) BG Height H % Area A % FWHM 1 12.854 6.8817 1670 876 13.1 8314 15.6 0.258 2 16.045 5.5194 1458 6663 100.0 53209 100.0 0.217 3 19.349 4.5836 1328 1428 21.4 10284 19.3 0.196 4 24.786 3.5891 1403 1421 21.3 10676 20.1 0.204 5 25.738 3.4586 1432 1641 24.6 12382 23.3 0.205 6 26.191 3.3997 1418 1875 28.1 15407 29.0 0.223 7 32.051 2.7902 1292 579 8.7 5877 11.0 0.276 8 32.486 2.7539 1269 181 2.7 3136 5.9 0.472 9 35.509 2.5260 1159 112 1.7 2723 5.1 0.660 10 36.011 2.4920 1122 174 2.6 2305 4.3 0.361 11 44.499 2.0344 1089 251 3.8 3794 7.1 0.411

Table 5 depicts the experimental X-ray powder diffraction of hydrated MoO₂Cl₂obtained after exposure of MoO₂Cl₁₂to ambient atmosphere for several hours.

In the drawings and specification, there have been disclosed certain embodiments of the invention and, although specific terms are employed, they are used in a generic and descriptive sense only and not for purposes of limitation, the scope of the invention being set forth in the following claims.

Claims

1. A compound having a formula MoO2Cl2 in crystalline form and orthorhombic crystal system and unit cell dimensions of about

a=13.552 Å α=90°

b=5.456 Å β=90°

c=5.508 Å γ=90°.

2. The compound of claim 1, which exhibits a powder X-ray diffraction (XRD) pattern with one or more peaks at 12.94, 23.64, 26.10, 39.50, and/or 40.28±0.04 degrees 2-theta.

3. The compound of claim 1, which has a powder X-ray diffraction (XRD) pattern comprises peak at about 6.776Å and about 3.7268Å.